JP2006317577A - Display device, electronic equipment, and camera - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a display device that is displayed with proper brightness so as not to damage easiness of seeing. <P>SOLUTION: The display device 100 of a an electronic camera 2 can select display of three modes of [A] a normal display mode, [B] a first high image quality display mode, and [C] a second high image quality display mode. The electronic camera 2 performs display of the display device 100 by [A] the normal display mode when being set at a photographing mode and a setting menu mode. The electronic camera 2 performs display of the display device 100 by [B] the first high image quality mode when being set at a reproduction mode. When it is determined that an image to be reproduced and displayed is photographed under backlight in the reproduction mode, display of the display device 100 is performed by [C] the second high image quality display mode. When thumbnail confirmation is instructed in the reproduction mode, display of the display device 100 is performed by [A] the normal display mode. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a display device that displays an image and the like, a camera including the display device, and an electronic apparatus.

  2. Description of the Related Art There is known a display device that visualizes an image formed on a light image forming element by illuminating a transmissive light image forming element composed of a liquid crystal panel or the like from the back. The user of the display device observes the light image transmitted through the light image forming element. The display brightness of this type of display device is increased by brightening illumination light (so-called backlight light). Patent Document 1 discloses a display device that performs a high luminance display by forming a backlight with a cold cathode fluorescent lamp and a light emitting diode array and brightening illumination light.

JP 2003-140110 A

  If the display device is always displayed with high brightness, it may be too dazzling to impair visibility.

A display device according to the present invention is disposed between a transmissive light image forming element that forms an image according to display data, an illuminating means that illuminates the light image forming element, and between the illuminating means and the light image forming element. A dimming means for reducing the amount of illumination light from the means, a normal display mode for setting the illuminating means to the first light emission amount and minimizing the dimming rate by the dimming means in response to a display change instruction, Display control means for controlling the illumination means and the light control means respectively so as to switch between a high image quality display mode that makes the second light emission quantity larger than one light emission quantity and minimizes the light reduction rate by the light control means. It is characterized by.
In the display device according to claim 1, the dimming rate of the light control means may be controlled in units of a predetermined area on the optical image forming element, and the display control means in this case further includes a display change instruction, The illumination means is set to a third light emission amount larger than the second light emission amount, and the illumination light amount for illuminating the area on the optical image forming element corresponding to the display data whose display luminance indicated by the display data is not more than a predetermined value is reduced. The illumination unit and the dimming unit can also be controlled so as to switch to the second high-quality display mode.
A camera according to the present invention includes: the display device according to claim 2; an imaging unit that captures a subject image and outputs image data; and a shooting mode that displays an image based on the image data output from the imaging unit on the display device; An operation member that emits a signal for setting one of a reproduction mode for displaying an image based on the recorded image data on the display device and a menu mode for displaying the menu information on the display device. The display control means is configured to control the illumination means and the dimming means so as to switch the display mode according to the above.
4. The camera according to claim 3, wherein the display control means switches to the normal display mode when the signal from the operation member indicates either the photographing mode or the menu mode, and when the signal from the operation member indicates the reproduction mode. It is also possible to control the illumination means and the dimming means so as to switch to the high-quality display mode.
5. The camera according to claim 4, wherein the display control means is a case where a signal from the operation member indicates a reproduction mode, and the display data includes a number of data corresponding to a predetermined low luminance or lower and a predetermined high luminance or higher, respectively. When there are a predetermined number or more, the illumination unit and the dimming unit can be controlled to switch from the high-quality display mode to the second high-quality display mode.
5. The camera according to claim 4, wherein the display control means is configured to display the high-quality display mode when the signal from the operation member indicates a reproduction mode and a signal instructing thumbnail display is further emitted from the operation member. The illumination unit and the dimming unit can be controlled so as to switch to the normal display mode.
5. The camera according to claim 4, wherein the display control means switches to the normal display mode once when the signal from the operation member is in the reproduction mode, and changes to the high quality display mode when the same image is displayed for a predetermined time in the normal display mode. Switching control can also be performed.
An electronic apparatus according to the present invention includes the display device according to claim 1 or 2.

  ADVANTAGE OF THE INVENTION According to this invention, the display apparatus, camera, and electronic device which display with appropriate brightness so that visibility may be impaired can be provided.

The best mode for carrying out the present invention will be described below with reference to the drawings.
(First embodiment)
FIG. 1 is a diagram illustrating a photo viewer 1 according to the first embodiment of the present invention. The photo viewer 1 displays a reproduced image based on the image data on the display device 100. The display image is an image recorded on a recording medium such as a memory card or an image supplied from an external device to the photo viewer 1 via an interface. An instruction to select a display image for the photo viewer 1 is input from the operation member 54.

  2A and 2B are diagrams for explaining the configuration of the display device 100 mounted on the photo viewer 1. FIG. 2A is a front view and FIG. 2B is a side view. In FIG. 2A, the display device 100 displays an image, text, or the like in the effective display area 100a.

  In FIG. 2B, the display device 100 is configured by laminating a first display module 13 and a second display module 14. The two display modules 13 and 14 stacked are illuminated from the first display module 13 side by the backlight member. The backlight member is composed of a high-intensity white LED 11 and a light guide plate 12. The high-intensity white LED 11 changes the light emission luminance at the time of lighting according to a drive current supplied from a control circuit described later. The light emission luminance is configured to be adjustable between, for example, a high level (maximum lighting luminance) and a normal level (normal luminance) that is 1/4 of the high level.

  The light guide plate 12 has an area larger than at least the effective display area 100a. The light guide plate 12 is emitted from the white LED 11, and the light incident on the light guide plate 12 from the side surface of the light guide plate 12 (below in FIG. 2B) is converted into surface illumination light having a uniform luminance within the effective display area 100a. Then, the first display module is illuminated with the surface illumination light.

  FIG. 3A is an enlarged view of a part of FIG. 2B in order to explain the internal structure of the display device 100. In FIG. 3A, the first display module 13 is constituted by, for example, a monochrome liquid crystal display element in which a known TN liquid crystal panel 13c is sandwiched between a first polarizing plate 13a and a second polarizing plate 13b. The The polarization direction of the light passing through the second polarizing plate 13b and the polarization direction of the light passing through the first polarizing plate 13a are arranged to be 90 degrees different from each other.

  In a state where no voltage is applied from a transparent electrode (not shown), the liquid crystal panel 13c rotates the polarization direction of the light incident on the liquid crystal layer by 90 degrees by the arrangement (orientation) of the liquid crystal molecules in the liquid crystal layer. As a result, the polarized light incident on the liquid crystal panel 13c via the first polarizing plate 13a is rotated by 90 degrees in the liquid crystal layer, and then passes through the second polarizing plate 13b, thereby causing the first display module 13 to rotate. And is incident on the second display module 14 as illumination light.

  On the other hand, in the liquid crystal panel 13c to which a voltage is applied from a transparent electrode (not shown), the arrangement of the liquid crystal molecules in the liquid crystal layer changes and the polarization direction of incident light is not rotated by 90 degrees. Thereby, since the polarized light incident on the liquid crystal panel 13c through the first polarizing plate 13a cannot pass through the second polarizing plate 13b, the amount of transmitted light emitted from the first display module 13 is reduced. . Since the change in the alignment of the liquid crystal molecules is proportional to the applied voltage, the rotation ratio of the polarization direction of light traveling through the liquid crystal layer is also proportional to the applied voltage. Accordingly, the amount of illumination light that passes through the first display module 13 and enters the second display module 14 decreases as the voltage applied to the liquid crystal panel 13c increases.

  The liquid crystal panel 13c is configured to be able to apply an arbitrary voltage corresponding to a drive signal input from a display control circuit, which will be described later, based on an image signal for each predetermined region (pixel) divided in a matrix. Thereby, the illumination light quantity incident on the second display module 14 can be increased or decreased in units of pixels.

  The second display module 14 is configured by, for example, a well-known TFT color liquid crystal display element in which a color filter 14a is sandwiched between a liquid crystal panel 14c and a polarizing plate 14b. The liquid crystal panel 14c is arranged so that the alignment direction on the incident surface side (first display module 13 side) matches the polarization direction of light passing through the second polarizing plate 13b. The polarization direction of the light passing through the polarizing plate 14b is disposed so as to be 90 degrees different from the polarization direction of the light passing through the second polarizing plate 13b.

  In a state where no voltage is applied from a transparent electrode (not shown), the liquid crystal panel 14c rotates the polarization direction of light incident on the liquid crystal layer by 90 degrees due to the alignment of the liquid crystal molecules in the liquid crystal layer. As a result, the polarized light incident on the liquid crystal panel 14c via the first display module 13 is rotated by 90 degrees in the liquid crystal layer, and then passes through the color filter 14a and the polarizing plate 14b to form the second display module. 14 is injected.

  On the other hand, the liquid crystal panel 14c to which a voltage is applied from a transparent electrode (not shown) changes the orientation of the liquid crystal molecules in the liquid crystal layer and does not rotate the polarization direction of incident light by 90 degrees. As a result, the polarized light incident on the liquid crystal panel 14c cannot pass through the polarizing plate 14b after passing through the color filter 14a, so that the amount of transmitted light emitted from the second display module 14 is reduced.

  The color filter 14a is, for example, one in which color filters of RGB colors are alternately arranged. The liquid crystal panel 14c is configured to be able to apply an arbitrary voltage corresponding to a drive signal input from a display control circuit, which will be described later, based on the image signal for each predetermined region (color filter subpixel) divided in a matrix. Has been. Thereby, the amount of transmitted light emitted from the second display module 14 can be increased or decreased in units of colors.

  FIG. 3B and FIG. 3C are diagrams for explaining predetermined areas divided in a matrix in the liquid crystal panel 13c and the liquid crystal panel 14c, respectively. In FIG.3 (b), the pixel of the liquid crystal panel 13c is comprised by substantially square shape. The amount of illumination light incident on the second display module 14 can be adjusted for each substantially square shape.

  In FIG. 3C, the sub-pixels of the liquid crystal panel 14c are configured such that one set of RGB corresponds to one pixel (substantially square shape) in FIG. That is, the amount of illumination light incident on the second display module 14 can be adjusted for each set of RGB subpixels.

  The effective display area 100a of the display device 100 corresponds to the effective display area of the second display module 14, and the effective display area of the first display module 13 is configured to be at least wider than the effective display area 100a. The light guide plate 12, the first display module 13, and the second display module 14 described above are overlapped so as to be in close contact with each other, and constitute the display device 100.

  In the display device 100, the second display module 14 modulates the light from the white LED 11 in accordance with the supplied image signal, thereby generating light images of RGB colors. Since the driving of the liquid crystal panel 14c constituting the second display module 14 is performed in the same manner as a known driving method for the liquid crystal display element, the description thereof is omitted. The user observes a full-color image synthesized by the RGB transmitted light emitted from the second display module 14.

  On the other hand, in the display device 100, the first display module 13 attenuates the light from the white LED 11 in accordance with the supplied image signal, thereby controlling the brightness of the observed image. The driving of the liquid crystal panel 13c constituting the first display module 13 is performed as follows.

(Black floating suppression by display device)
FIG. 4 shows the luminance indicated by the image signal (data displayed on the second display module 14) supplied to the display device 100 and the dimming rate of illumination light (transmission of illumination light) performed by the first display module 13. It is a figure explaining the relationship with (rate). In FIG. 4, the horizontal axis represents data luminance and is expressed as a percentage of the maximum value (full scale) input of the input signal of the display device 100. The vertical axis represents the transmittance of illumination light, and is expressed as a percentage with respect to a state in which no voltage is applied to the electrodes of the liquid crystal panel 13c (for convenience, the transmittance is 100%).

  According to FIG. 4, when the luminance level of the data of the image signal (luminance of at least one color of RGB) exceeds a predetermined threshold (for example, 5% of full scale), the liquid crystal panel 13c corresponding to this image signal No voltage is applied to the matrix region. That is, in the region where the luminance level exceeds 5% of the full scale, the transmittance of the illumination light amount by the first display module 13 is maximized (the light attenuation rate is minimized), and the illumination light amount incident on the second display module 14 is Maximize.

  Further, when the luminance level of the image signal data (the luminance of all RGB) is 5% or less of the full scale, the matrix region of the liquid crystal panel 13c corresponding to this image signal has a transmittance proportional to the luminance level. Thus, a voltage is applied to each pixel. That is, in the region where the luminance level corresponds to 5% of the full scale, the transmittance of the illumination light amount by the first display module 13 is maximized (the light attenuation rate is minimized), and the illumination light amount incident on the second display module 14 Increase Further, in a region where the luminance level is less than 5% of the full scale, the transmittance of the illumination light amount by the first display module 13 is gradually decreased (the dimming rate is gradually increased), and the second display module 14 is. The amount of illumination light incident on is gradually reduced. Furthermore, in the region where the luminance level corresponds to 0% of full scale, the illumination of the amount of illumination light by the first display module 13 is minimized (maximum dimming rate), and the illumination incident on the second display module 14. The amount of light is reduced to approximately zero.

  As a result, the amount of illumination light that illuminates a region that is desired to be darkly expressed in the display screen (that is, a region where the transmittance of the liquid crystal panel 14c constituting the second display module 14 is minimized) is reduced. Even if a complete light-shielding state cannot be obtained by 14c, the absolute level of the RGB color transmitted light transmitted through the liquid crystal panel 14c in this region is kept small. As a result, the user does not observe the black float in the observation image. Further, the luminance of the light source can be increased by the amount that the black float can be reduced, and as a result, the dynamic range of the display image can be increased.

  A luminance level of 5% of full scale corresponds to 12.5 LSB, for example, when the image signal is expressed in 8-bit full scale. Further, when the image signal is expressed in 12-bit full scale, it corresponds to 204LSB.

(Photo viewer)
FIG. 5 is a block diagram illustrating a configuration of a main part of the photo viewer 1 of FIG. The photo viewer 1 is selected from a predetermined image recorded on the memory card 53 (for example, an image designated in advance by an operation signal from the operation member 54) or an image recorded on the memory card 53 by the CPU 51. An image or an image supplied from an external device via the external interface 52 is reproduced and displayed on the display device 100.

  The CPU 51 performs an image display operation by sending a control signal to each part of the photo viewer 1 by performing a predetermined calculation using a signal input from each part in the photo viewer 1 based on the control program. Control. The control program is stored in a nonvolatile memory (not shown) in the CPU 51.

  The operation member 54 outputs an operation signal corresponding to the user's operation to the CPU 51. The memory card 53 is configured by a nonvolatile memory such as a flash memory, and data can be written, stored, and read according to instructions from the CPU 51. The external interface 52 communicates with an external device such as an electronic camera or a personal computer according to a command from the CPU 51. An image signal received through communication is input to the CPU 51.

  The display control circuit 15 generates signals for driving the second display module 14 and the first display module 13 in accordance with display data output from the CPU 51, and the second display module 14 and Each of the first display modules 13 is driven.

  The display control circuit 15 further turns on the backlight 11 with the instructed luminance in accordance with the lighting instruction output from the CPU 51. The lit backlight 11 illuminates the second display module 14 via the first display module 13.

  In the photo viewer 1 described above, in order to display a reproduced image based on the image data recorded on the memory card 53 on the display device 100, the CPU 51 reads the image data from the memory card 53, and uses the read image data to display the display device. Display data corresponding to the number of display pixels of 100 is generated, and the generated display data is sent to the display control circuit 15 as an image signal. Further, a backlight lighting instruction is sent to the display control circuit 15 together with a lighting luminance instruction. The display data includes luminance level information of each pixel in the second display module 14. The display control circuit 15 determines the transmittance of the illumination light amount by the first display module 13, that is, the reduction rate of the illumination light amount, using the luminance level information indicated by the display data, and controls the illumination light amount.

(Display mode of display device)
The display device 100 is configured to be able to switch between the following three display modes separately from the above-described suppression of black floating. The display control circuit 15 that receives the switching instruction from the CPU 51 controls the display mode by controlling the lighting luminance of the backlight 11 and the transmittance of the illumination light amount by the first display module 13.

[A] Normal Display Mode In the normal display mode, the lighting brightness of the backlight 11 is set to a normal level (= normal brightness = ¼ of the maximum lighting brightness), the black floating suppression is turned off, and the first display is performed. The transmittance of the illumination light quantity is maximized in all the pixels of the module 13. In this case, the upper limit of the gradation expressed by the display device 100 is the first display module 13 in which the normal luminance illumination light from the backlight 11 is set to the maximum transmittance, and the maximum transmittance (so-called white display). This corresponds to the level of light transmitted through the second display module 14 set to. The lower limit of the gradation expressed by the display device 100 is set to the first display module 13 in which the normal luminance illumination light from the backlight 11 is set to the maximum transmittance and the minimum transmittance (so-called black display). This corresponds to the level of light transmitted through each of the second display modules 14.

[B] First High Quality Display Mode In the first high quality display mode, the lighting brightness of the backlight 11 is set to twice the normal level (= 1/2 of the maximum lighting brightness), and the above-described black floating suppression is turned off. At the same time, the transmittance of the amount of illumination light is maximized in all the pixels of the first display module 13. The upper limit of the gradation expressed by the display device 100 is set to the first display module 13 in which the illumination light of double brightness by the backlight 11 is set to the maximum transmittance and the maximum transmittance (so-called white display). This corresponds to the level of light transmitted through the second display module 14. The lower limit of the gradation expressed by the display device 100 is set to the first display module 13 in which the illumination light of double brightness by the backlight 11 is set to the maximum transmittance and the minimum transmittance (so-called black display). This corresponds to the level of light transmitted through the second display module 14. Compared with the normal display mode, the brightness of the display image is improved while the display dynamic range is the same.

[C] Second High Quality Display Mode In the first high quality display mode, the lighting brightness of the backlight 11 is set to a high level (= maximum lighting brightness = four times the normal brightness), and the amount of illumination by the first display module 13 Is controlled according to the luminance level of the display data (black floating suppression is on). The upper limit of the gradation expressed by the display device 100 is set to the first display module 13 in which the illumination light of 4 times luminance from the backlight 11 is set to the maximum transmittance and the maximum transmittance (so-called white display). This corresponds to the level of light transmitted through the second display module 14. The lower limit of the gradation expressed by the display device 100 is the first display module 13 in which the illumination light of 4 times luminance from the backlight 11 is set to the minimum transmittance (black floating suppression), and the minimum transmittance (so-called so-called). This corresponds to the level of light transmitted through each of the second display modules 14 set to black display. Compared with the first high-quality mode, the brightness of the display image is improved (the upper limit of the gradation is increased) and the lower limit of the gradation is decreased, so that the display dynamic range is expanded.

(Partial high quality display)
The photo viewer 1 of the first embodiment displays a part of the display screen of the display device 100 in the [C] second high-quality display mode, and the remaining part of the display screen is the same as in the [A] normal display mode. Display with brightness and display dynamic range.

  FIG. 6 is a diagram illustrating an example of an image displayed on the display device 100 by the photo viewer 1. FIG. 6A shows an image formed by the second display module 14, and FIG. 6B shows an image formed by the first display module 13. As described above, the image observed by the user is the image of FIG. 6 (a) that is transmitted and illuminated by the illumination light pattern shown in FIG. 6 (b).

  In FIG. 6A, the reproduction display image 61 is displayed near the right side of the screen, and the information (Exif information) added to the data of the reproduction image is displayed in text in the left margin area 62 of the reproduction display image. Has been. In the example of FIG. 6A, as the Exif information, the image data file name “XXXX YYYY”, the image data recording format “JPEG (Normal)”, the number of pixels “1600 × 1200”, the shooting date “200x.xx”, The shutter speed and aperture value “1/30 sec F / 2.6” are displayed as shooting conditions. Items to be displayed as Exif information can be changed as appropriate by an operation from the operation member 54.

  The user operates the operation member 54 while viewing the image displayed on the display device 100 and information related to the image, and switches the display image or displays the entire screen (only the image is displayed without displaying the Exif information). Display) or display an image with Exif information.

  When an operation signal is input from the operation member 54 so as to display an image together with Exif information, the CPU 51 sends a command to the display control circuit 15 so as to set the lighting luminance of the backlight 11 to a high level (four times luminance). . The CPU 51 further controls the transmittance of the first display module 13 so that the luminance of the illumination light that illuminates other areas except the reproduced display image 61 on the second display module 14 is uniformly reduced to ¼. At the same time, for the area corresponding to the reproduced display image 61 on the second display module 14, the above-described black floating suppression is performed.

  According to FIG. 6B, the transmitted light amount of the region 63 is ¼ of the maximum transmittance, and the transmitted light amount of the region 64 is a value corresponding to the display luminance of the reproduced display image 61 (FIG. 6A). The amount of transmitted light in the region 65 is controlled to the maximum (that is, the maximum transmittance). As a result, the user observes [C] the reproduction display image 61 displayed in the wide dynamic range in the second high image quality display mode, and the Exif information 62 displayed in the normal luminance similar to the [A] normal display mode. it can.

(full screen)
When the operation signal is input from the operation member 54 so as to display the entire screen, the CPU 51 sends a command to the display control circuit 15 so as to set the lighting luminance of the backlight 11 to a high level (four times luminance). Further, the CPU 51 once controls the transmittance of the first display module 13 so as to maximize the illumination light luminance that illuminates the entire area on the second display module 14, and then performs the above-described black floating suppression. . As a result, the user can observe the reproduced display image displayed in the wide dynamic range in the [C] second high image quality display mode.

According to the first embodiment described above, the following operational effects can be obtained.
(1) The display device 100 of the photo viewer 1 is configured to be able to select three modes of display: [A] normal display mode, [B] first high quality display mode, and [C] second high quality display mode. Therefore, it is possible to display with brightness and dynamic range according to the user's request. [A] In the normal display mode, since the current supplied to the backlight 11 may be small, the power consumption can be suppressed, and it is not too dazzling to impair visibility. In [A] normal display mode and [B] first high image quality display mode, the transmittance of the illumination light only needs to be fixed to the maximum uniformly in the entire area of the first display module 13, so that the control becomes simple.

(2) When displaying an image together with Exif information on the display device 100 of the photo viewer 1, only the image portion is displayed with high image quality, so that the user observes an image displayed in a bright and wide dynamic range. be able to. On the other hand, since the area other than the image and including the Exif information is displayed in the same way as the normal display, the background brightness is too high, for example, when displaying a black character on a white background. It is possible to prevent the legibility of the character information from being impaired due to the dazzling effect. The area 63 on the first display module 13 can be controlled easily because the transmittance of the illumination light is uniformly fixed to ¼ of the maximum transmittance.

  The threshold for changing the transmittance of the amount of illumination light by the first display module 13 in suppressing black floating is not limited to 5% illustrated in FIG. 4 and may be changed as appropriate, such as 3% or 15%.

  Moreover, you may make it the structure which changes according to the brightness | luminance of the illumination light by the backlight members 11 and 12 about the threshold value mentioned above. FIG. 7 is a diagram for explaining the relationship between the luminance (light source luminance) of illumination light by the backlight members 11 and 12 and the threshold (threshold). In FIG. 7, the horizontal axis represents the light source luminance, and the vertical axis represents the threshold value.

  According to FIG. 7, the threshold value is changed to be higher as the light source luminance increases. For example, the threshold value is changed in a range of about 5% to about 10% of the full scale in proportion to the increase of the light source luminance. As a result, the transmitted light of RGB color that passes through an area that is desired to be darkly expressed in the display screen (that is, an area in which the transmittance of the liquid crystal panel 14c constituting the second display module 14 is minimized) has a light source luminance. Even in a high case, the absolute level can be kept small. As a result, the user does not observe the black float in the observation image.

  The control may be switched according to the number of gradations of the image signal supplied to the display device 100 (the bit length of gradation expression). In this case, for example, when the number of gradations of the image signal is expressed by 8 bits, the transmittance of the illumination light amount by the first display module 13 is maximized over the entire effective display area 100a, and the second display module 14 is Maximize the brightness of the illumination light. On the other hand, when the number of gradations of the image signal is expressed as 12 bits or 16 bits, as described above, the amount of illumination light that passes through the first display module 13 and illuminates the second display module 14 is transmitted. The rate is dimmed in a predetermined area unit (in the above example, for each set of RGB sub-pixels) according to the supplied image signal.

(Second embodiment)
FIG. 8 is a diagram illustrating the electronic camera 2 according to the second embodiment of the present invention. The electronic camera 2 displays on the display device 100 a preview image before shooting (so-called through image), a monitor image after shooting (so-called freeze image), a playback image based on data recorded on a memory card, and a setting menu. . An operation input from the operation member 54 includes a switching of a shooting mode, a playback mode and a setting menu mode, a shooting instruction, a playback image selection instruction, and the like for the electronic camera 2.

  FIG. 9 is a block diagram illustrating a configuration of a main part of the electronic camera 2 of FIG. Based on the control program, the CPU 51 performs a predetermined calculation using signals input from each unit in the electronic camera 2 and sends a control signal to each unit of the electronic camera 2, thereby performing shooting operation, auto Controls focus adjustment operation and image display operation. The control program is stored in a nonvolatile memory (not shown) in the CPU 51.

  The operation member 54 outputs an operation signal corresponding to the user's operation to the CPU 51. The memory card 53 is configured by a non-volatile memory such as a flash memory, and is capable of writing and storing photographed image data and reading image data according to instructions from the CPU 51. The external interface 52A communicates with an external device such as a personal computer in response to a command from the CPU 51.

  The imaging device 150 includes an imaging device composed of a CCD image sensor, a CMOS image sensor, or the like, and captures a subject image in response to a command output from the CPU 51. The imaging device 150 further performs predetermined signal processing on the imaging signal, converts the signal-processed data into image data of a predetermined format, and outputs the image data to the CPU 51.

  Since the display device 100 is the same as that mounted on the photo viewer 1 of the first embodiment, detailed description thereof is omitted. The display device 100 is configured to be able to switch between [A] normal display mode, [B] first high image quality display mode, and [C] second high image quality display mode even when mounted on the electronic camera 2. Yes.

  The electronic camera 2 displays any one of the above-described [A] normal display mode, [B] first high-quality display mode, and [C] second high-quality display mode according to the set operation mode. Switch to

(Shooting mode and setting menu mode)
When an operation signal is input from the operation member 54 so as to set the electronic camera 2 to the photographing mode or the setting menu mode, the CPU 51 displays the display control circuit so that the lighting luminance of the backlight 11 is set to a normal level (normal luminance). Send a command to 15. The CPU 51 further controls the transmittance of the first display module 13 so as to maximize the illumination light luminance for the entire area on the second display module 14, and then turns off the above-described black float suppression. . As a result, the user can observe the playback display image (through image and freeze image) displayed in the [A] normal display mode and the setting menu screen.

(Focus confirmation in shooting mode)
Further, when an operation signal for instructing focus confirmation is input from the operation member 54 in the photographing mode, the CPU 51 sends a command to the display control circuit 15 to set the lighting luminance of the backlight 11 to a high level (four times luminance). . The CPU 51 further controls the transmittance of the first display module 13 so that the illumination light luminance that illuminates the area other than the area corresponding to the focus area on the second display module 14 is uniformly reduced to ¼. For the area corresponding to the focus area on the second display module 14, the above-described black floating suppression is performed. The focus area is an area in the shooting screen where focus adjustment information is acquired for performing autofocus adjustment, and is assumed to be provided at the center of the shooting screen in this embodiment. The CPU 51 calculates a lens driving amount based on the acquired focus adjustment information, and instructs a lens driving mechanism (not shown) to perform focus lens driving according to the lens driving amount. Thereby, autofocus adjustment is performed.

  FIG. 10 is a diagram illustrating an example of an image displayed on the display device 100 by the electronic camera 2 instructed to confirm focus. 10A shows an image formed by the second display module 14, and FIG. 10B shows an image formed by the first display module 13. The image observed by the user is the image of FIG. 10A that is transmitted and illuminated by the illumination light pattern shown in FIG.

  According to FIG. 10B, the transmitted light amount in the region 73 excluding the focus area is 1/4 of the maximum transmittance, and the transmitted light amount in the region 74 is the display image 71 corresponding to the focus area (FIG. 10A). The amount of transmitted light in the region 75 is controlled to the maximum (that is, the maximum transmittance) to a value corresponding to the display brightness. As a result, the user can observe the display image 71 corresponding to the focus area as an image displayed in a wide dynamic range in the [C] second high image quality display mode. The display image other than the focus area can be observed as an image displayed at a normal luminance similar to that in the [A] normal display mode.

(Playback mode)
When an operation signal is input from the operation member 54 so as to set the electronic camera 2 to the playback mode, the CPU 51 sets the lighting luminance of the backlight 11 to twice the normal luminance (1/2 of the maximum lighting luminance). A command is sent to the display control circuit 15. Further, the CPU 51 controls the transmittance of the first display module 13 so as to maximize the illumination light luminance that illuminates the entire area on the second display module 14, and then turns off the above-described black floating suppression. To do. As a result, the user can observe the reproduced display image displayed in the [B] first high quality display mode.

  The CPU 51 further analyzes the luminance distribution of the image signal supplied to the display device 100. 11 and 12 are diagrams for explaining an example of a histogram showing the luminance distribution. FIG. 11 shows the luminance distribution of an image taken under direct light, and FIG. 12 shows the luminance distribution of an image taken under backlight. 11 and 12, the horizontal axis represents the luminance level of the pixels constituting the image, and the vertical axis represents the frequency, that is, the number of pixels (data number) corresponding to the luminance level.

  In general, a captured image under direct light controlled to an appropriate exposure has a lot of intermediate gradation data, and there is little high luminance data distributed to the right in the histogram. On the other hand, a captured image under backlight is roughly divided into high luminance data such as sunlight and low luminance data distributed to the left in the histogram.

  The CPU 51 determines that the image is under backlight if there are a predetermined number of data corresponding to a predetermined low luminance or lower and a predetermined high luminance or higher in the histogram, and the pixel corresponding to the right end of the histogram is less than the predetermined number. Is determined to be an image under normal light.

  The CPU 51 that has determined that the image is under the normal light sends a command to the display control circuit 15 so as to set the lighting luminance of the backlight 11 to a high level (four times luminance), and illuminates the entire area on the second display module 14. The transmittance of the first display module 13 is controlled so that the illumination light luminance is uniformly maximized, and the above-described black floating suppression is performed on the second display module 14. As a result, the user can observe the reproduced display image as an image displayed in a wide dynamic range in the [C] second high-quality display mode.

  Note that the histograms in FIGS. 11 and 12 are data examples created for the purpose of this description, and need not necessarily be created in actual determination processing. For example, data (number of pixels) whose luminance level is higher than or equal to the high luminance determination threshold value and lower than or equal to the low luminance determination threshold value for the data constituting the image may be counted, and the following light / back light may be determined according to this count value.

(Thumbnail display in playback mode)
When an operation signal for instructing thumbnail confirmation is input from the operation member 54 in the playback mode, the CPU 51 sends a command to the display control circuit 15 to set the lighting luminance of the backlight 11 to a normal level (normal luminance). Further, the CPU 51 controls the transmittance of the first display module 13 so as to maximize the illumination light luminance that illuminates the entire area on the second display module 14, and then turns off the above-described black floating suppression. To do. As a result, the user can observe the thumbnail image displayed in the [A] normal display mode.

According to the second embodiment described above, the following operational effects can be obtained.
(1) When the electronic camera 2 is set to the shooting mode and the setting menu mode, the display of the display device 100 is displayed in the [A] normal display mode, so that the composition is confirmed from the display image in the shooting mode. In the case where it is sufficient to know the menu contents in the setting menu mode, it is possible to automatically switch to the display mode suitable for each. [A] By setting the normal display mode, the control of the first display module 13 is simplified and the power consumption by the backlight 11 is also suppressed. Furthermore, when displaying a black character on a white background, it is possible to prevent the visibility of character information from being impaired due to glare caused by excessively high background luminance.

(2) When the focus confirmation is instructed in the shooting mode, only the image portion corresponding to the focus area is displayed with high image quality, so that the focus area portion is brighter than images other than the focus area and has a wide dynamic range. This makes it easier to check the focus adjustment status.

(3) When the electronic camera 2 is set to the playback mode, the display on the display device 100 is displayed in the [B] first high-quality display mode, so that the display mode suitable for viewing the captured image is automatically set. You can switch to [B] By setting the first high-quality display mode, a brightly displayed reproduced image can be viewed.

(4) When it is determined that the image to be reproduced and displayed in the reproduction mode is captured under backlight, the display on the display device 100 is displayed in the [C] second high image quality display mode, so that it is bright and has a wide dynamic range. The displayed playback image can be viewed. [C] In the second high image quality display mode, unlike [A] normal display mode and [B] first high image quality display mode, the high luminance data and the low luminance data included in the image photographed under backlight are respectively appropriate. Can be displayed.

(5) When an instruction to confirm thumbnails is given in the playback mode, the display on the display device 100 is displayed in the [A] normal display mode, so that it is possible to automatically switch to a display mode suitable for thumbnail display. [A] By setting the normal display mode, the control of the first display module 13 is simplified and the power consumption by the backlight 11 is also suppressed.

(Modification 1)
When the playback mode is set, the display on the display device 100 may be performed once in the [A] normal display mode. In this case, the CPU 51 reproduces and displays the image of the predetermined image file read from the memory card 53 on the display device 100 in the [A] normal display mode, and then starts measuring time by the built-in timer. When the CPU 51 reproduces and displays the same image and measures a predetermined time (for example, 5 seconds), the CPU 51 switches the display of the display device 100 to the [B] first high-quality display mode. As a result, while the operation for switching the image to be reproduced and displayed is performed, [A] the normal display mode is displayed, and [B] the first high-quality display mode is automatically performed in a situation where the user carefully appreciates the display image. You can switch to It should be noted that when changing the display mode, the light source luminance is gradually changed to make it difficult for the observer to feel uncomfortable.

(Modification 2)
The example of switching the display mode of the display device 100 according to the luminance distribution of the image displayed in the playback mode has been described. However, the display mode is switched according to the scene mode of the image to be displayed and the recording format of the image data. Also good. The scene mode is one of setting items that the user sets in the electronic camera 2 in accordance with the shooting target. The electronic camera 2 is configured to perform exposure control, focus adjustment, and signal processing on an image signal during shooting according to a set scene mode. Information indicating the scene mode set at the time of shooting is added to the image data and recorded in the memory card 53.

  FIG. 13 is a diagram for explaining the relationship between the scene mode and the display mode. In FIG. 13, “Normal” in the display mode represents [A] normal display mode. “HDR-1” represents [B] the first high-quality display mode. “HDR-2” represents [C] second high quality display mode.

  When the scene mode is “auto”, the histogram “has a halftone”, and the file format is “RAW”, it corresponds to the case where it is determined that the image is captured under the direct light in the above-described playback mode. The file format “RAW” represents a recording format in which image signals are recorded without being subjected to signal processing.

  When the scene mode is “auto”, the histogram “biased up and down”, and the file format is “RAW”, it corresponds to the case where it is determined that the image is captured under backlight in the above-described playback mode. The histogram “(ALL)” indicates that it is not related to the luminance distribution of the image. The file format “(ALL)” indicates that it is irrelevant to the recording format of the image data.

  In the above description, the electronic camera 2 automatically switches the display mode of the display device 100. However, when an operation signal for switching the display mode is generated from the operation member 54, the display mode is changed according to the operation signal. Is configured to switch between.

  The display described in the first embodiment (when the image is displayed together with the Exif information on the display device 100, only the image portion is displayed in high quality) may be displayed on the display device 100 of the electronic camera 2.

  In addition to the photo viewer 1 and the electronic camera 2, the display device 100 may be used for an electronic device having a display screen such as an electronic book viewer, a computer monitor, a video monitor, and a television set.

It is a figure explaining the photo viewer by 1st embodiment of this invention. (a) It is a front view explaining the structure of a display apparatus. (b) It is a side view. (a) It is the figure which expanded a part. (b) It is a figure which shows the predetermined area | region divided | segmented into the matrix form in the TN liquid crystal panel. (c) It is a figure which shows the predetermined area | region divided | segmented into the matrix form in the liquid crystal panel. It is a figure explaining the relationship between data brightness | luminance and a light control rate. It is a block diagram explaining the principal part structure of a photo viewer. (a) It is a figure which shows the image formed by the 2nd display module. (b) It is a figure which shows the image formed by the 1st display module. It is a figure explaining the relationship between the brightness | luminance of illumination light, and a threshold value. It is a figure explaining the electronic camera by 2nd embodiment of this invention. It is a block diagram explaining the principal part structure of an electronic camera. (a) It is a figure which shows the image formed by the 2nd display module. (b) It is a figure which shows the image formed by the 1st display module. It is a figure explaining an example of the histogram which shows luminance distribution. It is a figure explaining an example of the histogram which shows luminance distribution. It is a figure explaining the relationship between a scene mode and a display mode.

Explanation of symbols

1 ... Photo viewer 2 ... Electronic camera 11 ... White LED
DESCRIPTION OF SYMBOLS 12 ... Light guide plate 13 ... 1st display module 13a, 13b, 14b ... Polarizing plate 13c (13d) ... Liquid crystal panel 14 ... 2nd display module 14a ... Color filter 14b ... Liquid crystal panel 15 ... Display control circuit 51 ... CPU
54 ... Operation member 100 ... Display device

Claims (8)

A transmissive optical image forming element that forms an image according to display data;
Illuminating means for illuminating the optical image forming element;
A dimming unit disposed between the illuminating unit and the optical image forming element to reduce the amount of illumination light from the illuminating unit;
In accordance with a display change instruction, a normal display mode in which the illumination unit is set to the first emission amount and the dimming rate by the dimming unit is minimized, and the illumination unit is set to a second emission amount larger than the first emission amount. And a display control means for controlling the illuminating means and the dimming means so as to switch between a high-quality display mode that minimizes the dimming rate by the dimming means. . The display device according to claim 1,
The dimming rate of the light control means is controlled in units of a predetermined area on the optical image forming element,
The display control means further sets the illumination means to a third light emission amount larger than the second light emission amount in response to a display change instruction, and the display data whose display luminance indicated by the display data is a predetermined value or less. A display device that controls each of the illumination unit and the light control unit so as to switch to a second high-quality display mode that reduces the amount of illumination light that illuminates a region on the optical image forming element corresponding to . A display device according to claim 2;
Imaging means for capturing a subject image and outputting image data;
A shooting mode for displaying an image based on image data output from the imaging means on the display device, a playback mode for displaying an image based on recorded image data on the display device, and a menu for displaying menu information on the display device An operation member that emits a signal for setting one of the modes,
The display control means controls the illumination means and the dimming means, respectively, so as to switch a display mode in accordance with a signal from the operation member. The camera according to claim 3.
The display control means switches to the normal display mode when the signal from the operation member indicates either the photographing mode or the menu mode, and the high-quality display mode when the signal from the operation member indicates the reproduction mode. The camera is characterized in that the illumination means and the light control means are controlled so as to be switched to each other. The camera according to claim 4, wherein
The display control means is a case where a signal from the operation member indicates a reproduction mode, and the display data includes a predetermined number of data corresponding to a predetermined low luminance or lower and a predetermined high luminance or higher. The camera controls the illumination unit and the dimming unit so as to switch from the high-quality display mode to the second high-quality display mode. The camera according to claim 4, wherein
The display control means switches from the high-quality display mode to the normal display mode when a signal from the operation member indicates a reproduction mode and a signal instructing thumbnail display is further issued from the operation member. Thus, the camera controls the illumination unit and the light control unit, respectively. The camera according to claim 4, wherein
The display control means switches to the normal display mode once when the signal from the operation member is in the reproduction mode, and controls to switch to the high-quality display mode when the same image is displayed for a predetermined time in the normal display mode. Camera characterized by.   An electronic apparatus comprising the display device according to claim 1.

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